P
US7681406B2ExpiredUtilityPatentIndex 92

Ice-making system for refrigeration appliance

Assignee: ELECTROLUX HOME PROD INCPriority: Jan 13, 2006Filed: Jan 13, 2006Granted: Mar 23, 2010
Est. expiryJan 13, 2026(expired)· nominal 20-yr term from priority
Inventors:CUSHMAN ROBERT LHALL DAVID LSCOVILLE JAMESHOLLAND JAMES RBERTOLACCINI ANDREAZUCCOLO STEFANOFAVRETTI ENRICOHSIN HUANG
F25C 1/24F25D 17/06F25D 2323/021F25D 2317/061F25D 2317/067F25D 2317/0666F25D 17/065F25C 2400/10F25C 1/08
92
PatentIndex Score
94
Cited by
26
References
58
Claims

Abstract

An ice-making system is adapted to operate within a section of a refrigeration appliance where the ice-making system and the ice made in the ice-making system are exposed to a temperature greater than zero degrees Centigrade. When installed in the fresh food compartment of a refrigerator that also has a freezer section compartment, the refrigeration system furnishes a cooling effect to the freezer compartment sufficient to maintain the freezer compartment at a temperature of zero degrees or less and separately furnish to the ice-making unit a cooling effect sufficient to freeze water for making ice in the ice-making unit of the ice-making system. The ice-making system can include a reservoir that is operatively associated with the ice-making unit of the ice-making system for delivering water to the ice-making unit and for receiving water returned from the ice-making unit.

Claims

exact text as granted — not AI-modified
1. A refrigeration appliance comprising:
 a freezer compartment maintained at a temperature of zero degrees Centigrade or less and a fresh food compartment maintained at a temperature greater than zero degrees Centigrade; 
 the freezer compartment and the fresh food compartment being in fluid communication with one another whereby air may be circulated between the freezer compartment and fresh food compartment; 
 a separate access door provided to each of the freezer compartment and the fresh food compartment, each separate access door being exposed to an ambient environment of the refrigeration appliance and openable to grant access to one of the freezer compartment and the fresh food compartment without exposing another of the freezer compartment and the fresh food compartment to the ambient environment; 
 an air mover for circulating air between the freezer compartment and the fresh food compartment; 
 an ice-making unit located in the fresh food compartment and including an ice-making tray adapted to contain a pool of water and a plurality of ice-forming elements disposed in the pool of water, the ice-making unit and the ice made in the ice-making unit being exposed to the temperature in the fresh food compartment, the ice-making unit further including: 
 a dumping mechanism operatively associated with the ice-making tray for rotating the ice-making tray about the ice-making elements, the dumping mechanism including at least one rod coupled to a side of the ice-making tray and having a longitudinal axis, the ice-making tray rotating about the longitudinal axis of the rod from a first position where the ice-making elements are located within the ice-making tray to a second position where the ice-making tray has rotated out from under the ice-making elements and ice pieces formed on the ice elements are able to be harvested; and 
 a refrigeration system in operative association with the freezer compartment and the ice-making unit for furnishing to the freezer compartment a cooling effect sufficient to maintain the freezer compartment at a temperature of zero degrees Centigrade or less and for separately furnishing to the ice-making unit a cooling effect sufficient to freeze water and form ice in the ice-making unit, the refrigeration system further including: 
 a first evaporator in operative association with the freezer compartment for furnishing to the freezer compartment a cooling effect sufficient to maintain the freezer compartment at a temperature of zero degrees Centigrade or less; and 
 a second evaporator in operative association with the ice-making unit for furnishing to the ice-making unit a cooling effect sufficient to freeze water and form ice in the ice-making unit, the second evaporator providing a refrigerant to the plurality of ice-forming elements that are disposed in the pool of water, the ice-forming elements being made of a material that is a thermal conductor and the refrigerant being at a temperature sufficiently low to cause the water in the vicinity of the ice-forming elements to freeze and form the ice pieces on the plurality of ice-forming elements. 
 
   
   
     2. The refrigeration appliance of  claim 1  including:
 a heat-supplying arrangement in operative association with the ice-making unit for selectively furnishing to the ice-making unit a heating effect sufficient to free ice formed in the ice-making unit from any surface in the ice-making unit to which the ice may adhere. 
 
   
   
     3. The refrigeration appliance of  claim 2  wherein:
 the refrigeration system in addition to including the first evaporator and the second evaporator includes a compressing unit, a condensing unit and a refrigerant; 
 each of the compressing unit, the condensing unit, the first evaporator and the second evaporator has an entry side for the entry of the refrigerant and an exit side for the exiting of the refrigerant; 
 the exit side of the compressing unit is in fluid communication with the entry side of the condensing unit; 
 each of the entry side of the first evaporator and the entry side of the second evaporator is in fluid communication with the exit side of the condensing unit; and 
 each of the exit side of the first evaporator and the exit side of the second evaporator is in fluid communication with the entry side of the compressing unit. 
 
   
   
     4. The refrigeration appliance of  claim 3  wherein the refrigeration system further includes:
 a first capillary tube located between the exit side of the condensing unit and the entry side of the first evaporator so as to control the flow of the refrigerant to the first evaporator from the condensing unit and the temperature of the refrigerant in the first evaporator; and 
 a second capillary tube located between the exit side of the condensing unit and the entry side of the second evaporator so as to control the flow of the refrigerant to the second evaporator from the condensing unit and the temperature of the refrigerant in the second evaporator; and 
 wherein the first capillary tube and the second capillary tube are of such respective sizes that the temperature of the refrigerant in the second evaporator is greater than the temperature of the refrigerant in the first evaporator. 
 
   
   
     5. The refrigeration appliance of  claim 3  wherein the heat-supplying arrangement in operative association with the ice-making unit for selectively furnishing to the ice-making unit a heating effect sufficient to free ice formed in the ice-making unit from any surface in the ice-making unit to which the ice may adhere comprises:
 a fluid conduit connected to the exit side of the compressing unit and the entry side of the second evaporator for placing the exit side of the compressing unit in fluid communication with the entry side of the second evaporator whereby at least a portion of the refrigerant from the compressing unit may bypass the condensing unit and flow from the exit side of the compressing unit to the entry side of the second evaporator; and 
 a valve in operative association with the fluid conduit for selectively opening and closing the fluid conduit to the flow of the refrigerant from the exit side of the compressing unit to the entry side of the second evaporator. 
 
   
   
     6. The refrigeration appliance of  claim 5  wherein the refrigeration system includes:
 a control valve for the second evaporator in operative association with the condensing unit and the second evaporator for selectively opening and closing off the flow of the refrigerant to the second evaporator from the condensing unit. 
 
   
   
     7. The refrigeration appliance of  claim 6  wherein the refrigeration system includes:
 a control valve for the first evaporator in operative association with the condensing unit and the first evaporator for selectively opening and closing off the flow of the refrigerant to the first evaporator from the condensing unit. 
 
   
   
     8. The refrigeration appliance of  claim 5  wherein the refrigeration system includes:
 a first capillary tube located between the exit side of the condensing unit and the entry side of the first evaporator so as to control the flow of the refrigerant to the first evaporator from the condensing unit and the temperature of the refrigerant in the first evaporator; and 
 a second capillary tube located between the exit side of the condensing unit and the entry side of the second evaporator so as to control the flow of the refrigerant to the second evaporator from the condensing unit and the temperature of the refrigerant in the second evaporator; and 
 wherein the first capillary tube and the second capillary tube are of such respective sizes that the temperature of the refrigerant in the second evaporator is greater than the temperature of the refrigerant in the first evaporator. 
 
   
   
     9. The refrigeration appliance of  claim 8  wherein the refrigeration system includes:
 a control valve for the second evaporator in operative association with the condensing unit and the second evaporator for selectively opening and closing off the flow of the refrigerant to the second evaporator from the condensing unit. 
 
   
   
     10. The refrigeration appliance of  claim 9  wherein the refrigeration system includes:
 a control valve for the first evaporator in operative association with the condensing unit and the first evaporator for selectively opening and closing off the flow of the refrigerant to the first evaporator from the condensing unit. 
 
   
   
     11. The refrigeration appliance of  claim 1  including:
 a reservoir located in the fresh food compartment for holding water, the reservoir and the ice-making unit together comprising an ice-making system, the reservoir being adapted to be in fluid communication with a source of water outside the refrigeration appliance whereby water from the source of water outside the refrigeration appliance may be delivered to the reservoir, and wherein the reservoir is in fluid communication with the ice-making unit both for the delivery of water from the reservoir to the ice-making unit and for the return of water from the ice-making unit to the reservoir. 
 
   
   
     12. The refrigeration appliance of  claim 11  including:
 a float valve operatively associated with the source of water outside the refrigeration appliance and the reservoir for controlling the delivery of water to the reservoir from the source of water outside the refrigeration appliance. 
 
   
   
     13. The refrigeration appliance of  claim 12  including:
 a pump operatively associated with the reservoir and the ice-making unit for pumping water from the reservoir to the ice-making unit. 
 
   
   
     14. The refrigeration appliance of  claim 11  wherein the ice-making unit includes:
 a collection area for collecting excess water from the ice-making tray and initially collecting the ice pieces after they are formed, the collection area including at least one opening through which the water may pass, and the at least one opening in the collection area being in fluid communication with the reservoir for returning the water from the collection area to the reservoir. 
 
   
   
     15. The refrigeration appliance of  claim 14  wherein:
 the ice-making unit includes an ice storage area for holding ice pieces formed by the ice-making unit. 
 
   
   
     16. The refrigeration appliance of  claim 15  wherein the ice storage area includes:
 at least one opening through which water may pass, the at least one opening in the ice storage area being in fluid communication with the reservoir for returning water from the ice storage area to the reservoir. 
 
   
   
     17. The refrigeration appliance of  claim 16  including:
 a device for moving the ice pieces from the collection area to the ice storage area. 
 
   
   
     18. The refrigeration appliance of  claim 17  including:
 a cover for the ice-making unit that covers at least the ice-storage area and limits the amount of moisture that can pass from the ice-making unit to the fresh food compartment. 
 
   
   
     19. The refrigeration appliance of  claim 11  including:
 a food or beverage storage unit located sufficiently proximate the reservoir so that the storage unit is cooled by the water in the reservoir. 
 
   
   
     20. A refrigeration appliance comprising:
 a freezer compartment maintained at a temperature of zero degrees Centigrade or less and a fresh food compartment maintained at a temperature greater than zero degrees Centigrade; 
 the freezer compartment and the fresh food compartment being in fluid communication with one another whereby air may be circulated between the freezer compartment and fresh food compartment; 
 an air mover for circulating air between the freezer compartment and the fresh food compartment; 
 an ice-making unit located in the fresh food compartment, the ice-making unit and the ice made in the ice-making unit being exposed to the temperature in the fresh food compartment; and 
 a refrigeration system in operative association with the freezer compartment and the ice-making unit for furnishing to the freezer compartment a cooling effect sufficient to maintain the freezer compartment at a temperature of zero degrees Centigrade or less and for separately furnishing to the ice-making unit a cooling effect sufficient to freeze water and form ice in the ice-making unit, 
 a reservoir located in the fresh food compartment for holding water, the reservoir and the ice-making unit together comprising an ice-making system, the reservoir being adapted to be in fluid communication with a source of water outside the refrigeration appliance whereby water from the source of water outside the refrigeration appliance may be delivered to the reservoir, and wherein the reservoir is in fluid communication with the ice-making unit both for the delivery of water from the reservoir to the ice-making unit and for the return of water from the ice-making unit to the reservoir; and 
 a food or beverage storage unit located sufficiently proximate the reservoir so that the storage unit is cooled by the water in the reservoir, wherein 
 the reservoir includes walls having inside surfaces that are in contact with and confine the water in the reservoir and outer surfaces, the walls of the reservoir being configured so that the storage unit is at least partially contained within the confines of the outer surfaces of the walls of the reservoir whereby the storage unit is cooled by the water in the reservoir. 
 
   
   
     21. The refrigeration appliance of  claim 20  including:
 a fan operatively associated with the storage unit for circulating the air within the storage unit. 
 
   
   
     22. A refrigeration appliance comprising:
 a freezer compartment maintained at a temperature of zero degrees Centigrade or less and a fresh food compartment maintained at a temperature greater than zero degrees Centigrade; 
 the freezer compartment and the fresh food compartment being in fluid communication with one another whereby air may be circulated between the freezer compartment and fresh food compartment; 
 an air mover for circulating air between the freezer compartment and the fresh food compartment; 
 an ice-making unit located in the fresh food compartment, the ice-making unit and the ice made in the ice-making unit being exposed to the temperature in the fresh food compartment; and 
 a refrigeration system in operative association with the freezer compartment and the ice-making unit for furnishing to the freezer compartment a cooling effect sufficient to maintain the freezer compartment at a temperature of zero degrees Centigrade or less and for separately furnishing to the ice-making unit a cooling effect sufficient to freeze water and form ice in the ice-making unit, 
 a reservoir located in the fresh food compartment for holding water, the reservoir and the ice-making unit together comprising an ice-making system, the reservoir being adapted to be in fluid communication with a source of water outside the refrigeration appliance whereby water from the source of water outside the refrigeration appliance may be delivered to the reservoir, and wherein the reservoir is in fluid communication with the ice-making unit both for the delivery of water from the reservoir to the ice-making unit and for the return of water from the ice-making unit to the reservoir; and 
 a door for closing off as well as providing access to the fresh food compartment, a dispensing port in the door of the fresh food compartment and a water dispensing path extending between the dispensing port and the reservoir along which water from the reservoir may flow to the dispensing port. 
 
   
   
     23. The refrigeration appliance of  claim 22  wherein:
 the water-dispensing path is arranged so as to be located essentially entirely within the fresh food compartment prior to entering the dispensing port. 
 
   
   
     24. The refrigeration appliance of  claim 1  wherein:
 the compressing unit comprises a single compressor and the condensing unit comprises a single condenser. 
 
   
   
     25. The refrigeration appliance of  claim 1  wherein:
 the compressing unit comprises a first compressor and a second compressor, the first compressor being in fluid communication with the first evaporator and the second compressor being in fluid communication with the second evaporator. 
 
   
   
     26. The refrigeration appliance of  claim 1  wherein:
 the compressing unit comprises a variable speed compressor, the speed and capacity of which are matched to the loads developed by the freezer compartment and the fresh food compartment, including the ice-making unit, of the refrigeration appliance. 
 
   
   
     27. A refrigeration system adapted to be used with a refrigeration appliance that includes a freezer compartment maintained at a temperature of zero degrees Centigrade or less, a fresh food compartment maintained at a temperature greater than zero degrees Centigrade and an ice-making unit located in the fresh food compartment, the ice-making unit and the ice made in the ice-making unit being exposed to the temperature of the fresh food compartment, the refrigeration system comprising:
 a refrigerant; 
 a compressing unit for compressing the refrigerant and having an entry side and an exit side; 
 a condensing unit for condensing the refrigerant after it has been compressed and having an entry side in fluid communication with the exit side of the compressing unit and an exit side; 
 a first evaporator having an entry side in fluid communication with the exit side of the condensing unit for receiving a first portion of the refrigerant and adapted to be operatively associated with the freezer compartment for furnishing a cooling effect to the freezer compartment sufficient to maintain the freezer compartment at a temperature of zero degrees Centigrade or less; 
 a second evaporator having an entry side in fluid communication with the exit side of the condensing unit independently of the first evaporator for receiving a second portion of the refrigerant and adapted to be operatively associated with the ice-making unit for furnishing a cooling effect to the ice-making unit sufficient to freeze water and form ice in the ice-making unit, the second evaporator providing the second portion of the refrigerant to an ice-making tray containing a pool of water, the second portion of the refrigerant being at a temperature sufficiently low to cause the water in the ice making tray, via a thermal conductor, to form ice pieces in the ice-making tray; 
 a fluid conduit connecting the exit side of the compressing unit and the entry side of the second evaporator for placing the exit side of the compressing unit in fluid communication with the entry side of the second evaporator whereby at least another portion of the refrigerant from the compressing unit may bypass the condensing unit and flow from the exit side of the compressing unit to the entry side of the second evaporator; 
 a valve operatively associated with the fluid conduit for selectively opening and closing the fluid conduit to the flow of compressed refrigerant from the exit side of the compressing unit to the entry side of the second evaporator; 
 a first capillary tube having an entry end and an exit end, the entry end of the first capillary tube being in fluid communication with the exit side of the condensing unit and the exit end of the first capillary tube being in fluid communication with the entry side of the first evaporator that is operatively associated to cool the freezer compartment; and 
 a second capillary tube having an entry end and an exit end, the entry end of the second capillary tube being in fluid communication with the exit side of the condensing unit and the exit end of the second capillary tube being in fluid communication with the entry side of the second evaporator that is operatively associated to furnish the cooling effect to the ice-making unit, 
 wherein the first capillary tube and the second capillary tube are of such respective sizes that the temperature of the refrigerant in the second evaporator is greater than the temperature of the refrigerant in the first evaporator when the refrigerant is being delivered to both the first and second evaporators. 
 
   
   
     28. The refrigeration system of  claim 27  wherein:
 the compressing unit comprises a single compressor and the condensing unit comprises a single condenser. 
 
   
   
     29. The refrigeration system of  claim 27  wherein:
 the compressing unit comprises a first compressor and a second compressor, the first compressor being in fluid communication with the first evaporator and the second compressor being in fluid communication with the second evaporator; and
 the fluid conduit connects the exit side of the second compressor and the entry side of the second evaporator. 
 
 
   
   
     30. The refrigeration system of  claim 27  including:
 a control valve for the second evaporator in operative association with the condensing unit and the second evaporator for selectively opening and closing off the flow of the refrigerant to the second evaporator from the condensing unit. 
 
   
   
     31. The refrigerator system of  claim 30  including:
 a control valve for the first evaporator in operative association with the condensing unit and the first evaporator for selectively opening and closing off the flow of the refrigerant to the first evaporator from the condensing unit. 
 
   
   
     32. The refrigeration system of  claim 31  including:
 a control mechanism operatively associated with the valve located in the fluid conduit for controlling the opening and closing of the valve for selected time periods. 
 
   
   
     33. The refrigeration system of  claim 32  including:
 a control valve for the second evaporator in operative association with the condensing unit and the second evaporator for selectively opening and closing off the flow of the refrigerant to the second evaporator from the condensing unit. 
 
   
   
     34. The refrigerator system of  claim 33  including:
 a control valve for the first evaporator in operative association with the condensing unit and the first evaporator for selectively opening and closing off the flow of the refrigerant to the first evaporator from the condensing unit. 
 
   
   
     35. An ice-making system comprising:
 an ice-making unit adapted to operate within a section of a refrigeration appliance that is maintained at a temperature above zero degrees Centigrade and to be placed in operative association with a refrigeration system for furnishing to the ice-making unit a cooling effect sufficient to freeze water and form ice in the ice-making unit, the ice-making unit and the ice made in the ice-making unit being exposed to the temperature of the section of the refrigeration appliance that is maintained at a temperature above zero degrees Centigrade; and 
 a reservoir for holding water, the reservoir being adapted to be located within the same section of the refrigeration appliance as the ice-making unit and further adapted to be in fluid communication with a source of water outside the refrigeration appliance whereby water from the source of water may be delivered to the reservoir, a valve for automatically controlling the delivery of water to the reservoir from the source of water outside the refrigerator appliance in response to the quantity of water in the reservoir, the reservoir being in fluid communication with the ice-making unit whereby water from the reservoir may be delivered to the ice-making unit and water from the ice-making unit may be returned to the reservoir, 
 a filter disposed between the source of water outside the refrigerator appliance and the reservoir to filter water from the source of water outside the refrigerator before the water is delivered to the reservoir; 
 the ice-making unit further including an ice storage area for holding ice pieces formed by the ice-making unit, and 
 the ice storage area including at least one opening through which water may pass, the at least one opening being in fluid communication with the reservoir for returning water from the ice storage area to the reservoir, such that said water returned from the ice storage area to the reservoir may be delivered to the ice-making unit; 
 the ice-making unit further including: 
 an ice-making tray adapted to contain a pool of water and a plurality of ice-forming elements disposed in the pool of water; and 
 a dumping mechanism operatively associated with the ice-making tray for rotating the ice-making tray about the ice-making elements, the dumping mechanism including at least one rod coupled to a side of the ice-making tray and having a longitudinal axis, the ice-making tray rotating about the longitudinal axis of the rod from a first position where the ice-making elements are located within the ice-making tray to a second position where the ice-making tray has rotated out from under the ice-making elements and the ice pieces formed on the ice elements are able to be harvested. 
 
   
   
     36. The ice-making system of  claim 35  wherein the valve is a float valve. 
   
   
     37. The ice-making system of  claim 36  including:
 a pump operatively associated with the reservoir and the ice-making unit for pumping and delivering water from the reservoir to the ice-making unit. 
 
   
   
     38. The ice-making system of  claim 35  wherein:
 the ice-making unit includes a collection area for collecting excess water from the ice-making tray and initially collecting the ice pieces, the collection area including at least one opening through which water may pass, the at least one opening being in fluid communication with the reservoir for returning water from the collection area to the reservoir. 
 
   
   
     39. The ice-making system of  claim 38  including:
 a device for moving the ice pieces from the collection area to the ice storage area. 
 
   
   
     40. The ice-making system of  claim 39  including:
 a cover for the ice-making unit that covers at least the ice-storage area and limits the amount of moisture that can pass from the ice-making unit to the fresh food compartment. 
 
   
   
     41. A method of operating a refrigeration appliance comprising a freezer compartment and a fresh food compartment in which an ice-making unit is located so that the ice-making unit and the ice pieces made thereby are exposed to the temperature in the fresh food compartment, the freezer compartment and the fresh food compartment each selectively enclosed by a separate access door but being in fluid communication with one another whereby air may be circulated between the freezer compartment and the fresh food compartment, wherein one of the separate access doors is openable to grant access to one of the freezer compartment and the fresh food compartment without exposing another of the freezer compartment and the fresh food compartment to the ambient environment, the method comprising:
 providing to the freezer compartment a cooling effect sufficient to maintain the freezer compartment at a temperature of zero degrees Centigrade or less; 
 circulating air between the freezer compartment and the fresh food compartment while maintaining the fresh food compartment at a temperature greater than zero degrees Centigrade; 
 providing to the ice-making unit in the fresh food compartment a cooling effect separate from the cooling effect provided to the freezer compartment, the cooling effect provided to the ice-making unit being sufficient to freeze water and form the ice pieces in the ice-making unit, 
 the cooling effect to the freezer compartment being provided by means of a first evaporator and the cooling effect to the ice-making unit being provided by means of a second evaporator, each of the first and second evaporators being independently supplied with first and second portions of a refrigerant, respectively, 
 the method further including the steps of: 
 filtering water from a source of water outside the refrigerator appliance with a filter provided to the refrigeration along a water line extending between the source of water outside the refrigerator appliance and a reservoir for storing filtered water within the fresh food compartment of the refrigerator appliance; 
 providing from the reservoir a pool of filtered water within an ice-making tray in the ice-making unit; 
 providing the second portion of refrigerant, via the second evaporator, to a plurality of ice-forming elements that are disposed in the pool of filtered water, the ice-forming elements being made of a material that is a thermal conductor and the second portion of refrigerant being at a temperature sufficiently low to cause the filtered water in the vicinity of the ice-forming elements to freeze; 
 forming the ice pieces on the plurality of ice-forming elements; 
 rotating the ice-making tray about a longitudinal axis of at least one rod coupled to a side of the ice-making tray from a first position where the ice-making elements are located within the ice-making tray to a second position where the ice-making tray has rotated out from under the ice-making elements and ice pieces formed on the ice elements are able to be harvested; 
 releasing from the ice-making tray any filtered water that has not been made into ice; 
 freeing the ice pieces from the plurality of ice-forming elements; and 
 at least a portion of the filtered water released from the ice-making tray is returned to the reservoir of water; and 
 rotating the ice-making tray about the longitudinal axis of the at least one rod back to the first position. 
 
   
   
     42. The method of  claim 41  wherein:
 the cooling effect to the ice-making unit is discontinued when ice is not being formed in the ice-making unit. 
 
   
   
     43. The method of  claim 42  wherein:
 the cooling effect to the freezer compartment is discontinued for at least a portion of the time that the cooling effect is provided to the ice-making unit. 
 
   
   
     44. The method of  claim 41  wherein the ice pieces are freed from the plurality of ice-forming elements by:
 providing to the ice-forming elements another portion of refrigerant that is at a temperature sufficiently great enough to break the bond causing the ice pieces to adhere to the ice-forming elements. 
 
   
   
     45. The method of  claim 44  wherein:
 the cooling effect to the ice-making unit is discontinued when ice is not being formed in the ice-making unit. 
 
   
   
     46. The method of  claim 45  wherein:
 the cooling effect to the freezer compartment is discontinued for at least a portion of the time that the cooling effect is provided to the ice-making unit. 
 
   
   
     47. The method of  claim 41  wherein:
 water is provided to the ice-making tray from the reservoir of water to an extent that the water overflows the ice-making tray; and 
 at least a portion of the water that overflows the ice-making tray is returned to the reservoir of water. 
 
   
   
     48. The method of  claim 47  wherein;
 the freed ice pieces are allowed to fall and are initially collected in a collection area of the ice-making unit located below the ice-making tray. 
 
   
   
     49. The method of  claim 48  wherein;
 the ice pieces are moved from the collection area to an ice storage area located in the fresh food compartment. 
 
   
   
     50. The method of  claim 49  wherein;
 any water resulting from the melting of the ice pieces in the ice storage area is returned to the reservoir of water. 
 
   
   
     51. A method of operating a refrigeration appliance having a freezer compartment and a fresh food compartment in which an ice-making unit is located so that the ice-making unit and the ice pieces made thereby are exposed to the temperature in the fresh food compartment, the freezer compartment and the fresh food compartment being in fluid communication with one another whereby air may be circulated between the freezer compartment and the fresh food compartment, the method comprising:
 providing to the freezer compartment a cooling effect sufficient to maintain the freezer compartment at a temperature of zero degrees Centigrade or less; 
 circulating air between the freezer compartment and the fresh food compartment while maintaining the fresh food compartment at a temperature greater than zero degrees Centigrade; 
 providing to the ice-making unit in the fresh food compartment a cooling effect separate from the cooling effect provided to the freezer compartment, the cooling effect provided to the ice-making unit being sufficient to freeze water and form the ice pieces in the ice-making unit, 
 wherein the cooling effect to the freezer compartment is provided by means of a first evaporator and the cooling effect to the ice-making unit is provided by means of a second evaporator, 
 wherein the ice pieces are made in the ice-making unit by: 
 providing from a source of water a pool of water within an ice-making tray in the ice-making unit; 
 providing a refrigerant to a plurality of ice-forming elements that are disposed in the pool of water, the ice-forming elements being made of a material that is a thermal conductor and the refrigerant being at a temperature sufficiently low to cause the water in the vicinity of the ice-forming elements to freeze; 
 forming the ice pieces on the plurality of ice-forming elements; 
 releasing from the ice-making tray any water that has not been made into ice; and 
 freeing the ice pieces from the plurality of ice-forming elements, 
 wherein the ice pieces are freed from the plurality of ice-forming elements by: 
 providing to the ice-forming elements a refrigerant that is at a temperature sufficiently great enough to break the bond causing the ice pieces to adhere to the ice-forming elements, 
 wherein the source of water is a reservoir of water located in the fresh food compartment of the refrigeration appliance; and 
 at least a portion of the water released from the ice-making tray is returned to the reservoir of water, 
 wherein water is provided to the ice-making tray from the reservoir of water to an extent that the water overflows the ice-making tray; and 
 at least a portion of the water that overflows the ice-making tray is returned to the reservoir of water, 
 wherein the freed ice pieces are allowed to fall and are initially collected in a collection area of the ice-making unit located below the ice-making tray, wherein the ice pieces are moved from the collection area to an ice storage area located in the fresh food compartment, 
 wherein any water resulting from the melting of the ice pieces in the ice storage area is returned to the reservoir of water, and 
 the method further including the step of dispensing water from the water reservoir through a dispensing port in a door that closes off the fresh food compartment to the ambient air in which the refrigeration appliance is located. 
 
   
   
     52. The method of  claim 51  including;
 using the water reservoir to cool a food or beverage cooling unit. 
 
   
   
     53. The ice-making system of  claim 35 , wherein water passing through the at least one opening included in the ice storage area is filtered by the filter in fluid communication with the reservoir before being returned to the reservoir to be subsequently delivered to the ice-making unit. 
   
   
     54. The method of  claim 41 , further including the step of filtering at least a portion of the filtered water released from the ice-making tray that is being returned to the reservoir with the filter provided to the refrigeration appliance to filter the water from the source of water outside the refrigerator appliance. 
   
   
     55. The refrigeration appliance of  claim 1 , further including a gearing mechanism operatively associated with the rod and adapted to rotate the rod to thereby rotate the ice-making tray. 
   
   
     56. The refrigeration appliance of  claim 55 , further including a collection area for initially collecting the ice pieces after they are formed, and a device for moving the ice pieces from the collection area to an ice storage area, the device being operatively associated with the gearing mechanism. 
   
   
     57. The refrigeration appliance of  claim 1 , wherein the freezer compartment and the access door provided to the freezer compartment are arranged substantially vertically below the fresh food compartment and the door provided to the fresh food compartment. 
   
   
     58. The refrigeration appliance of  claim 57  further comprising a dispensing port formed in the access door provided to the fresh food compartment in communication with the ice-making unit to dispense ice from the ice-making tray to the ambient environment.

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